Explanation Given information: The magnitude of the force P is 200 N. The angle the force makes with the horizontal is θ = 35 ° . The coefficient of static friction is μ s = 0.20 . The coefficient of kinetic friction is μ k = 0.15 . Calculation: Show the free-body diagram of the block as in Figure 1. Consider initially the block is in equilibrium. Find the normal force (N) by resolving the vertical component of forces. + ↗ ∑ F y = 0 N − 800 × cos 25 ° + P × sin ( θ − 25 ° ) = 0 N − 800 cos 25 ° + 200 sin ( 35 ° − 25 ° ) = 0 N = 690.3 N ( ↑ ) Find the friction force (F) by resolving the horizontal component of forces. + ↘ ∑ F x = 0 − F + 800 × sin 25 ° − P × cos ( θ − 25 ° ) = 0 − F + 800 sin 25 ° − 200 cos ( 35 ° − 25 ° ) = 0 F = − 141

12th Edition

ISBN: 9781259977121

Author: BEER

Publisher: MCG

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Chapter 8.1, Problem 8.2P

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Find whether the block is in equilibrium.

Find the magnitude and direction of the friction force.

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Chapter 8.1, Problem 8.1P

Chapter 8.1, Problem 8.3P

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Chapter 8 Solutions

VECTOR MECHANICS FOR ENGINEERS: STATICS

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Find whether the block is in equilibrium. Find the magnitude and direction of the friction force.

Solution Summary: The author shows the free-body diagram of the block as in Figure 1. Find the normal force by resolving the vertical component of forces.

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Find whether the block is in equilibrium. Find the magnitude and direction of the friction force.

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Chapter 8 Solutions

Find whether the block is in equilibrium.

Find the magnitude and direction of the friction force.